A capacitive device includes a unit cell including a CMUT, and a transmission/reception plate for impedance matching which is provided above the unit cell via a connection portion, in which a membrane of the CMUT constituting the unit cell is connected to the transmission/reception plate via the connection portion having an area smaller than that of the transmission/reception plate. The area of the transmission/reception plate is desirably larger than the area of a hollow portion of the CMUT.

An acoustic lens (7) for an ultrasound transducer that is disposed in a front end portion of an ultrasound transducer (1) has a concave front surface (C1) and is formed from a base material (B) in which a plurality of fine particles (G) are dispersed. As a degree of dispersion of the fine particles (G) is higher from a central portion toward both end portions in an elevation direction, acoustic velocity is lower from the central portion toward both end portions in the elevation direction.

A deployable invasive device includes a transducer with a plurality of elements linked by at least one shape memory material configured to move the plurality of elements relative to one another between a first configuration and a second configuration in response to a stimulus. The shape memory material comprises at least one active region configured to facilitate transition between the first configuration and the second configuration. The deployable invasive device includes at least one integrated circuit configured to process signals from at least one of the plurality of elements and a plurality of conductive traces on or in the shape memory material and extending through the active region. The conductive traces are configured to conduct signals to the at least one integrated circuit, wherein the conductive traces are configured to conform as the shape memory material moves the elements between the first configuration and the second configuration.

A composition for an acoustic lens contains the following components (A) to (C): (A) a polysiloxane having a vinyl group, (B) a polysiloxane having two or more Si—H groups in a molecular chain thereof, and (C) alumina particles surface-treated with at least one surface treatment agent of an aminosilane compound, a mercaptosilane compound, an isocyanatosilane compound, a thiocyanatosilane compound, an aluminum alkoxide compound, a zirconium alkoxide compound, or a titanium alkoxide compound.

An ultrasonic sensor includes a two-dimensional array of ultrasonic transducers, a contact layer, a matching layer between the two-dimensional array and the contact layer, where the matching layer has a non-uniform thickness, and an array controller configured to control activation of ultrasonic transducers during an imaging operation for imaging a plurality of pixels within the two-dimensional array of ultrasonic transducers. During the imaging operation, the array controller is configured to activate different subsets of ultrasonic transducers associated with different regions of the two-dimensional array of ultrasonic transducers at different transmission frequencies, where the different frequencies are determined such that a thickness of the matching layer at a region is substantially equal to a quarter wavelength of the first transmission frequency for the region. The array controller is also configured to combine the plurality of pixels into a compound fingerprint image that compensates for the non-uniform thickness of the matching layer.

An ultrasonic transceiver includes a case having conductivity, a piezoelectric body having a piezoelectric electrode, and an adhesive member that bonds the case to the piezoelectric body. The adhesive member includes an adhesive and conductive particles, and secures electrical continuity between the case and the piezoelectric electrode. An adhesive layer formed of the adhesive member provided between the case and the piezoelectric electrode has a thickness equal to or less than a particle diameter of the conductive particles.

An ultrasonic-based system includes a transmitter and receiver, an ultrasonic transducer including ≥1 piezoelectric element having a matching layer thereon connected to the transmitter. A controller is coupled to the transmitter. The transmitter is for driving the piezoelectric element with a pulsed electrical signal, where the piezoelectric element transmits a transmit ultrasonic signal. A current/voltage measurement circuit is coupled to sense a current or voltage in the transmitter. The controller is for implementing an algorithm for an ultrasonic transducer monitoring method including comparing an amplitude of the pulsed signal to a predetermined limit. When the pulsed signal is determined to be outside the limit, an impedance of the piezoelectric element is determined to be abnormal. When the pulsed signal is within the limit, the amplitude of the received signal is compared to a lower limit, which when below results in determining a cleaning operation for the ultrasonic transducer is needed.

An imaging device includes a transducer that includes an array of piezoelectric elements formed on a substrate. Each piezoelectric element includes at least one membrane suspended from the substrate, at least one bottom electrode disposed on the membrane, at least one piezoelectric layer disposed on the bottom electrode, and at least one top electrode disposed on the at least one piezoelectric layer. Adjacent piezoelectric elements are configured to be isolated acoustically from each other. The device is utilized to measure flow or flow along with imaging anatomy.

A resonant type transducer transmitting or receiving narrowband continuous waves into or from a propagation medium, comprising a piezoelectric or electro strictive vibrator having a specific acoustic impedance; a single matching layer or multiple matching layers contacting the piezoelectric or electro strictive vibrator as well as the propagation medium to maximise power transfer to and from the transducer and the propagation medium. The equivalent specific acoustic impedance of the matching layers and propagation medium is complex conjugate to the equivalent specific acoustic impedance of the piezoelectric or electro strictive vibrator and backing layer at the frequency of operation resulting in reflection of the travelling wave in the layers resulting in in-phase addition and maximum power transfer.

Described are transducer assemblies and imaging devices comprising: a microelectromechanical systems (MEMS) die including a plurality of piezoelectric elements; a complementary metal-oxide-semiconductor (CMOS) die electrically coupled to the MEMS die by a first plurality of bumps and including at least one circuit for controlling the plurality of piezoelectric elements; and a package secured to the CMOS die by an adhesive layer and electrically connected to the CMOS die.